// Copyright 2024, Command Line Inc. // SPDX-License-Identifier: Apache-2.0 package wshutil import ( "bytes" "encoding/json" "fmt" "io" "log" "sync" ) const ( Mode_Normal = "normal" Mode_Esc = "esc" Mode_WaveEsc = "waveesc" BlockFile_Main = "main" // Assuming this is defined elsewhere ) const MaxBufferedDataSize = 256 * 1024 type PtyBuffer struct { CVar *sync.Cond DataBuf *bytes.Buffer EscMode string EscSeqBuf []byte OSCPrefix string InputReader io.Reader MessageCh chan RpcMessage AtEOF bool Err error } // closes messageCh when input is closed (or error) func MakePtyBuffer(oscPrefix string, input io.Reader, messageCh chan RpcMessage) *PtyBuffer { if len(oscPrefix) != WaveOSCPrefixLen { panic(fmt.Sprintf("invalid OSC prefix length: %d", len(oscPrefix))) } b := &PtyBuffer{ CVar: sync.NewCond(&sync.Mutex{}), DataBuf: &bytes.Buffer{}, OSCPrefix: oscPrefix, EscMode: Mode_Normal, InputReader: input, MessageCh: messageCh, } go b.run() return b } func (b *PtyBuffer) setErr(err error) { b.CVar.L.Lock() defer b.CVar.L.Unlock() if b.Err == nil { b.Err = err } b.CVar.Broadcast() } func (b *PtyBuffer) setEOF() { b.CVar.L.Lock() defer b.CVar.L.Unlock() b.AtEOF = true b.CVar.Broadcast() } func (b *PtyBuffer) processWaveEscSeq(escSeq []byte) { var helper RpcMessageUnmarshalHelper err := json.Unmarshal(escSeq, &helper) if err != nil { log.Printf("error unmarshalling Wave OSC sequence data: %v\n", err) return } if helper.Req != nil { b.MessageCh <- helper.Req } else { b.MessageCh <- helper.Res } } func (b *PtyBuffer) run() { defer close(b.MessageCh) buf := make([]byte, 4096) for { n, err := b.InputReader.Read(buf) b.processData(buf[:n]) if err == io.EOF { b.setEOF() return } if err != nil { b.setErr(fmt.Errorf("error reading input: %w", err)) return } } } func (b *PtyBuffer) processData(data []byte) { outputBuf := make([]byte, 0, len(data)) for _, ch := range data { if b.EscMode == Mode_WaveEsc { if ch == ESC { // terminates the escape sequence (and the rest was invalid) b.EscMode = Mode_Normal outputBuf = append(outputBuf, b.EscSeqBuf...) outputBuf = append(outputBuf, ch) b.EscSeqBuf = nil } else if ch == BEL || ch == ST { // terminates the escpae sequence (is a valid Wave OSC command) b.EscMode = Mode_Normal waveEscSeq := b.EscSeqBuf[WaveOSCPrefixLen:] b.EscSeqBuf = nil b.processWaveEscSeq(waveEscSeq) } else { b.EscSeqBuf = append(b.EscSeqBuf, ch) } continue } if b.EscMode == Mode_Esc { if ch == ESC || ch == BEL || ch == ST { // these all terminate the escape sequence (invalid, not a Wave OSC) b.EscMode = Mode_Normal outputBuf = append(outputBuf, b.EscSeqBuf...) outputBuf = append(outputBuf, ch) b.EscSeqBuf = nil continue } if ch != b.OSCPrefix[len(b.EscSeqBuf)] { // this is not a Wave OSC sequence, just an escape sequence b.EscMode = Mode_Normal outputBuf = append(outputBuf, b.EscSeqBuf...) outputBuf = append(outputBuf, ch) b.EscSeqBuf = nil continue } // we're still building what could be a Wave OSC sequence b.EscSeqBuf = append(b.EscSeqBuf, ch) // check to see if we have a full Wave OSC prefix if len(b.EscSeqBuf) == len(b.OSCPrefix) { b.EscMode = Mode_WaveEsc } continue } // Mode_Normal if ch == ESC { b.EscMode = Mode_Esc b.EscSeqBuf = []byte{ch} continue } outputBuf = append(outputBuf, ch) } if len(outputBuf) > 0 { b.writeData(outputBuf) } } func (b *PtyBuffer) writeData(data []byte) { b.CVar.L.Lock() defer b.CVar.L.Unlock() // only wait if buffer is currently over max size, otherwise allow this append to go through for b.DataBuf.Len() > MaxBufferedDataSize { b.CVar.Wait() } b.DataBuf.Write(data) b.CVar.Broadcast() } func (b *PtyBuffer) Read(p []byte) (n int, err error) { b.CVar.L.Lock() defer b.CVar.L.Unlock() for b.DataBuf.Len() == 0 { if b.Err != nil { return 0, b.Err } if b.AtEOF { return 0, io.EOF } b.CVar.Wait() } b.CVar.Broadcast() return b.DataBuf.Read(p) }